Newer
Older
m_header_info_signer_info(
m_issuerIdentifier_sha256AndDigest(
v_atCertificate.cracaId
valueof(m_header_info_generation_time(1000 * f_getCurrentTime())), // In us
valueof(m_header_info_generation_location(p_threeDLocation))
// Build the secured message and return it
return f_buildGnSecuredMessage(p_securedMessage, p_certificateName, p_payloadField/*, v_mandatoryHeaders*/);
} // End of function f_buildGnSecuredOtherMessage
/**
* @desc This function build and sign the SecureMessage part covered by the signature process including wrong elements of protocols. It is used for BO test cases
* @param p_securedMessage The signed SecureMessage part
* @param p_protocolVersion The protocol version to be set. Default: 2
* @param p_trailerStatus The Traile behaviour:
* <li>0 for no trailer</li>
* <li>1 for invalid trailer</li>
* <li>2 for duplicated trailer</li>
* @param p_payloadField Payloads to be included in the message
* @param p_signerIdentifierType Add digest or AT certificate or certificate chain
* @param p_headerInfo HeaderInfo to be inserted in the message
* @param p_certificateName The certificate identifier to be used. Default: TA_CERT_A
* @param p_addMissingHeaders Whether to add mandatory headers not present in p_headerInfo
* @return true on success, false otherwise
*/
function f_buildGnSecuredOtherMessage_Bo(
in ToBeSignedData p_payloadField,
in SignerIdentifier p_signerIdentifierType, // FIXME To be reviewed
in template (omit) HeaderInfo p_headerInfo := omit,
in boolean p_addMissingHeaders := true
) runs on ItsSecurityBaseComponent return boolean {
// Local variables
var EtsiTs103097Certificate v_aaCertificate, v_atCertificate;
var HeaderInfo v_mandatoryHeaders := {};
var HeaderInfo v_signerInfo;
// Load certificates if required
if (f_prepareCertificates(p_certificateName, v_aaCertificate, v_atCertificate) == false) {
return false;
}
// Add additional headers if required
/* FIXME To be reviewed if (p_addMissingHeaders == true) {
if (valueof(p_signerIdentifierType) == e_certificate) { // Add the AT certificate
m_header_info_signer_info(
m_signerIdentifier_certificate(
} else if (valueof(p_signerIdentifierType) == e_certificate_chain) { // Add the AT certificate + AA EtsiTs103097Certificate
m_header_info_signer_info(
m_signerIdentifier_certificates(
{
v_aaCertificate,
v_atCertificate
}
)
));
} else if (valueof(p_signerIdentifierType) == e_certificate_digest_with_sha256) { // Add the AT certificate digest
m_header_info_signer_info(
m_issuerIdentifier_sha256AndDigest(
v_atCertificate.cracaId
)));
}
v_mandatoryHeaders := {
v_signerInfo,
valueof(m_header_info_generation_time(1000 * f_getCurrentTime())), // In us
valueof(m_header_info_generation_location(p_threeDLocation))
// FIXME To be done
// Build the secured message and return it
return f_buildGnSecuredMessage(p_securedMessage, p_certificateName, p_payloadField/*, v_mandatoryHeaders*/);
} // End of function f_buildGnSecuredOtherMessage_Bo
} // End of group hostSignatureHelpers
group deviceSignatureHelpers {
/**
* @desc Retrieve the HashedId8 to be sent to the IUT, based on the provided certificate identifier
* @param p_certificateName The certificate the IUT shall use
* @return The HashedId8 to be sent to the IUT in the UtInitialize command
* @verdict Unchanged
* @remark Component variable vc_hashedId8ToBeUsed shall be set with the IUT certificate to be used
*/
function f_setupIutCertificate(
in charstring p_certificateName
) runs on ItsSecurityBaseComponent return HashedId8 {
// Local variables
// var EtsiTs103097Certificate v_atCertificate;
var HashedId8 v_hashedId8 := '0000000000000000'O;
// Sanity check
if (lengthof(p_certificateName) == 0) {
return v_hashedId8;
}
// Load certificates
if(f_getCertificateDigest(p_certificateName, v_hashedId8) == false) {
v_hashedId8 := '0000000000000000'O;
}
return v_hashedId8;
} // End of function f_setupIutCertificate
* @desc Verify the signature of the provided certificate
* @param p_certificateToBeVerified EtsiTs103097Certificate to be verified
* @param p_publicKey Public key to verify the certificate signature
* @return true on success, false otherwise
* @verdict
*/
function f_verifyCertificateSignatureWithPublicKey(
in template (value) EtsiTs103097Certificate p_certificateToBeVerified,
in template (value) EccP256CurvePoint p_publicKey
) return boolean {
// Local variables
var octetstring toBeVerifiedData;
var octetstring v_signature;
var template (value) ToBeSignedCertificate v_toBeSignedCertificate;
// Create EtsiTs103097Certificate payload to be verified
/* FIXME To be reviewed v_toBeSignedCertificate := m_toBeSignedCertificate(p_certificateToBeVerified);
toBeVerifiedData := bit2oct(encvalue(v_toBeSignedCertificate));
valueof(p_certificateToBeVerified.signature_.ecdsaNistP256Signature.rSig) &
valueof(p_certificateToBeVerified.signature_.ecdsaNistP256Signature.sSig);
log("toBeVerifiedData: ", toBeVerifiedData);
log("v_signature : ", v_signature);
v_result := f_verifyWithEcdsaNistp256WithSha256(
toBeVerifiedData,
v_signature,
valueof(p_publicKey.uncompressedP256.x),
valueof(p_publicKey.uncompressedP256.y)
);*/
} // End of finction f_verifyCertificateSignatureWithPublicKey
* @desc Verify the signature of the provided secured message
* @param p_certificateToBeVerified EtsiTs103097Certificate to be verified
* @param p_issuingCertificate Issuing certificate
* @return true on success, false otherwise
* @verdict
*/
function f_verifyCertificateSignatureWithIssuingCertificate(
in template (value) EtsiTs103097Certificate p_certificateToBeVerified,
in template (value) EtsiTs103097Certificate p_issuingCertificate
/* FIXME To be reviewed for (var integer v_counter := 0; v_counter < lengthof(p_issuingCertificate.subject_attributes); v_counter := v_counter + 1) {
if (valueof(p_issuingCertificate.subject_attributes[v_counter].type_) == e_verification_key) {
return f_verifyCertificateSignatureWithPublicKey(
p_certificateToBeVerified,
valueof(p_issuingCertificate.subject_attributes[v_counter].attribute.key));
} // End of function f_verifyCertificateSignatureWithIssuingCertificate
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* @desc Verify the signature of the provided secured message for ECDSA Nist-P256 algorithm
* @param p_securedMessage The message to be verified
* @param p_publicKey The ECDSA public key to verify a signature
* @param p_certificate EtsiTs103097Certificate to be used to verify the message
* @return true on success, false otherwise
* @verdict Unchanged
*/
function f_verifyGnSecuredMessageSignature_ecdsaNistP256(
in template (value) Ieee1609Dot2Data p_securedMessage,
in template (value) EccP256CurvePoint p_publicKey
) return boolean {
// Local variables
var octetstring v_secPayload;
var octetstring v_signedData;
var boolean v_result := false;
var template (value) ToBeSignedData v_toBeSignedData;
log(">>> f_verifyGnSecuredMessageSignature_ecdsaNistP256: p_securedMessage= ", p_securedMessage);
log(">>> f_verifyGnSecuredMessageSignature_ecdsaNistP256: p_publicKey= ", p_publicKey);
// Create Ieee1609Dot2Data payload to be signed
v_toBeSignedData := valueof(p_securedMessage.content.signedData.tbsData);
log("f_verifyGnSecuredMessageSignature_ecdsaNistP256: v_toBeSignedData=", p_securedMessage.content.signedData.tbsData);
v_secPayload := bit2oct(encvalue(v_toBeSignedData));
log("f_verifyGnSecuredMessageSignature_ecdsaNistP256: v_secPayload=", v_secPayload);
// Verify payload
v_signedData := valueof(p_securedMessage.content.signedData.signature_.ecdsaNistP256Signature.rSig.x_only) & valueof(p_securedMessage.content.signedData.signature_.ecdsaNistP256Signature.sSig);
log("f_verifyGnSecuredMessageSignature_ecdsaNistP256: v_signedData=", v_signedData);
v_result := f_verifyWithEcdsaNistp256WithSha256(
v_secPayload,
v_signedData,
valueof(p_publicKey.uncompressedP256.x),
valueof(p_publicKey.uncompressedP256.y)
);
log("f_verifyGnSecuredMessageSignature_ecdsaNistP256: v_result=", v_result);
return v_result;
} // End of function f_verifyGnSecuredMessageSignature_ecdsaNistP256
/**
* @desc Verify the signature of the provided secured message for ECDSA Brainpool-P256 algorithm
* @param p_securedMessage The message to be verified
* @param p_publicKey The ECDSA public key to verify a signature
* @param p_certificate EtsiTs103097Certificate to be used to verify the message
* @return true on success, false otherwise
* @verdict Unchanged
*/
function f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1(
in template (value) Ieee1609Dot2Data p_securedMessage,
in template (value) EccP256CurvePoint p_publicKey
) return boolean {
// Local variables
var octetstring v_secPayload;
var octetstring v_signedData;
var boolean v_result := false;
var template (value) ToBeSignedData v_toBeSignedData;
log(">>> f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: p_securedMessage= ", p_securedMessage);
log(">>> f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: p_publicKey= ", p_publicKey);
// Create Ieee1609Dot2Data payload to be signed
v_toBeSignedData := valueof(p_securedMessage.content.signedData.tbsData);
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: v_toBeSignedData=", p_securedMessage.content.signedData.tbsData);
v_secPayload := bit2oct(encvalue(v_toBeSignedData));
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: v_secPayload=", v_secPayload);
// Verify payload
v_signedData := valueof(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP256r1Signature.rSig.x_only) & valueof(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP256r1Signature.sSig);
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: v_signedData=", v_signedData);
v_result := f_verifyWithEcdsaBrainpoolp256WithSha256(
v_secPayload,
v_signedData,
valueof(p_publicKey.uncompressedP256.x),
valueof(p_publicKey.uncompressedP256.y)
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log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1: v_result=", v_result);
return v_result;
} // End of function f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1
/**
* @desc Verify the signature of the provided secured message for ECDSA Brainpool-P384 algorithm
* @param p_securedMessage The message to be verified
* @param p_publicKey The ECDSA public key to verify a signature
* @param p_certificate EtsiTs103097Certificate to be used to verify the message
* @return true on success, false otherwise
* @verdict Unchanged
*/
function f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1(
in template (value) Ieee1609Dot2Data p_securedMessage,
in template (value) EccP384CurvePoint p_publicKey
) return boolean {
// Local variables
var octetstring v_secPayload;
var octetstring v_signedData;
var boolean v_result := false;
var template (value) ToBeSignedData v_toBeSignedData;
log(">>> f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: p_securedMessage= ", p_securedMessage);
log(">>> f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: p_publicKey= ", p_publicKey);
// Create Ieee1609Dot2Data payload to be signed
v_toBeSignedData := valueof(p_securedMessage.content.signedData.tbsData);
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: v_toBeSignedData=", p_securedMessage.content.signedData.tbsData);
v_secPayload := bit2oct(encvalue(v_toBeSignedData));
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: v_secPayload=", v_secPayload);
v_signedData := valueof(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP384r1Signature.rSig.x_only) & valueof(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP384r1Signature.sSig);
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: v_signedData=", v_signedData);
v_result := f_verifyWithEcdsaBrainpoolp384WithSha384(
v_secPayload,
v_signedData,
valueof(p_publicKey.uncompressedP384.x),
valueof(p_publicKey.uncompressedP384.y)
);
log("f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1: v_result=", v_result);
} // End of function f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1
* @desc Verify the signature of the provided secured message
* @param p_securedMessage
* @param p_certificate EtsiTs103097Certificate to be used to verify the message
* @return true on success, false otherwise
* @verdict
*/
function f_verifyGnSecuredMessageSignatureWithCertificate(
in template (value) Ieee1609Dot2Data p_securedMessage,
in template (value) EtsiTs103097Certificate p_certificate
if (ischosen(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP256r1Signature)) {
return f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP256r1(p_securedMessage, p_certificate.toBeSigned.verifyKeyIndicator.verificationKey.ecdsaBrainpoolP256r1);
} else if (ischosen(p_securedMessage.content.signedData.signature_.ecdsaBrainpoolP384r1Signature)) {
return f_verifyGnSecuredMessageSignature_ecdsaBrainpoolP384r1(p_securedMessage, p_certificate.toBeSigned.verifyKeyIndicator.verificationKey.ecdsaBrainpoolP384r1);
} else if (ischosen(p_securedMessage.content.signedData.signature_.ecdsaNistP256Signature)) {
return f_verifyGnSecuredMessageSignature_ecdsaNistP256(p_securedMessage, p_certificate.toBeSigned.verifyKeyIndicator.verificationKey.ecdsaNistP256);
}
} // End of function f_verifyGnSecuredOtherMessageWithDeviceCertificate
} // End of group deviceSignatureHelpers
garciay
committed
* @desc return Ieee1609Dot2Data header field of given type or null if none
* @param p_msg the Ieee1609Dot2Data
* @return HeaderInfo of given type if any or null
in template(omit) Ieee1609Dot2Data p_securedMessage,
out HeaderInfo p_return
) return boolean {
if (not isvalue(p_securedMessage)) {
testcase.stop(__SCOPE__ & " can not handle omitted secured message values");
}
v_securedMessage := valueof(p_securedMessage);
if (ispresent(v_securedMessage.content.signedData)) {
p_return := v_securedMessage.content.signedData.tbsData.headerInfo;
return true;
}
}
/**
* @desc return SignerIdentifier Ieee1609Dot2Data field
in template(omit) Ieee1609Dot2Data p_securedMessage,
out SignerIdentifier p_signerIdentifier
) return boolean {
if (not isvalue(p_securedMessage)) {
testcase.stop(__SCOPE__ & " can not handle omitted secured message values");
}
if (ischosen(p_securedMessage.content.signedData)) {
p_signerIdentifier := valueof(p_securedMessage.content.signedData.signer);
return true;
}
log("f_getMsgSignerIdentifier: return false");
* @desc Set the generation location as defined in Draft ETSI TS 103 097 V1.1.14 Clause 7.2 Security profile for DENMs
* @param p_latitude The latitude value of the ITS-S position
* @param p_longitude The longitude value of the ITS-S position
* @param p_elevation The elevation value of the ITS-S position
* @verdict Unchanged
*/
function f_setGenerationLocation(
in SecLatitude p_latitude,
in SecLongitude p_longitude,
in SecElevation p_elevation := 0
) runs on ItsSecurityBaseComponent {
vc_location := {
p_elevation
}
} // End of function f_setGenerationLocation
* @desc Load in memory cache the certificates available
* @param p_configId A configuration identifier
* @remark This method SHALL be call before any usage of certificates
* @return true on success, false otherwise
*/
) runs on ItsSecurityBaseComponent return boolean {
// Setup certificates memory cache
if (fx_loadCertificates(PX_CERTIFICATE_POOL_PATH, p_configId) == true) {
// Setup security component variables
/*FIXME if(f_readCertificate(cc_taCert_A, vc_atCertificate)) {
if(f_readCertificate(oct2str(vc_atCertificate.issuer), vc_aaCertificate)) {
if(f_readSigningKey(cc_taCert_A, vc_signingPrivateKey)) {
f_readEncryptingKey(cc_taCert_A, vc_encryptPrivateKey);
return true;
}
log("f_loadCertificates: Failed to load signing key for ", cc_taCert_A);
}else{
log("f_loadCertificates: Failed to load AA certificate for ", cc_taCert_A);
log("f_loadCertificates: Failed to load AT certificate for ", cc_taCert_A);
log("f_loadCertificates: Failed to load certificates from ", PX_CERTIFICATE_POOL_PATH);
return false;
} // End of function f_loadCertificates
/**
* @desc Unload from memory cache the certificates available
* @return true on success, false otherwise
*/
function f_unloadCertificates() runs on ItsSecurityBaseComponent return boolean {
// Reset security component variables
vc_signingPrivateKey := '0000000000000000000000000000000000000000000000000000000000000000'O;
vc_encryptPrivateKey := '0000000000000000000000000000000000000000000000000000000000000000'O;
// Clear certificates memory cache
return fx_unloadCertificates();
} // End of function f_unloadCertificates
* @desc Read the specified certificate
* @param p_certificateId the certificate identifier
* @param p_certificate the expected certificate
* @return true on success, false otherwise
*/
) runs on ItsSecurityBaseComponent return boolean {
var octetstring v_certificate;
if (fx_readCertificate(p_certificateId, v_certificate) == true) {
var bitstring v_oct2bit;
var integer v_result;
v_oct2bit := oct2bit(v_certificate);
v_result := decvalue(v_oct2bit, p_certificate);
if (v_result == 0) {
return true;
}
}
log("f_readCertificate: Failed to retrieve ", p_certificateId);
} // End of function f_readCertificate
/**
* @desc Read the specified certificate
* @param p_certificateId the certificate identifier
* @param p_certificate the expected certificate
* @return true on success, false otherwise
*/
function f_getCertificateDigest(
in charstring p_certificateId,
out HashedId8 p_digest
) runs on ItsSecurityBaseComponent return boolean {
if( not fx_readCertificateDigest(p_certificateId, p_digest)){
log("f_getCertificateDigest: Failed to retrieve digest for ", p_certificateId);
return false;
}
return true;
} // End of function f_getCertificateDigest
* @desc Read the signing private key for the specified certificate
* @param p_keysId the keys identifier
* @param p_signingPrivateKey the signing private key
* @return true on success, false otherwise
*/
function f_readSigningKey(
in charstring p_keysId,
out Oct32 p_signingPrivateKey
) runs on ItsSecurityBaseComponent return boolean {
return fx_readSigningKey(p_keysId, p_signingPrivateKey);
} // End of function f_readSigningKey
/**
* @desc Read the encrypting private keys for the specified certificate
* @param p_keysId the keys identifier
* @param p_encryptPrivateKey the encrypt private key
* @return true on success, false otherwise
*/
function f_readEncryptingKey(
) runs on ItsSecurityBaseComponent return boolean {
return fx_readEncryptingKey(p_keysId, p_encryptPrivateKey);
} // End of function f_readEncryptingKey
function f_getCertificateValidityRestriction(
in template (value) EtsiTs103097Certificate p_cert,
out template (value) ValidityPeriod p_validityPeriod,
out template (omit) GeographicRegion p_geographicRegion
) return boolean {
p_validityPeriod := valueof(p_cert.toBeSigned.validityPeriod);
if (ispresent(p_cert.toBeSigned.region)) {
p_geographicRegion := valueof(p_cert.toBeSigned.region);
} else {
p_geographicRegion := omit;
}
} // End of function f_getCertificateValidityRestriction
group certificatesCaching {
function f_createCertificatesCaching(
out CertificatesCaching p_certificatesCaching
) return boolean {
p_certificatesCaching := { };
for (var integer v_counter := 0; v_counter < lengthof(p_certificates); v_counter := v_counter + 1) {
var CertificatesCachingItem v_item;
v_item.certificate := p_certificates[v_counter];
v_item.hashedId8 := f_calculateDigestSha256FromCertificate(v_item.certificate);
p_certificatesCaching[v_counter] := v_item;
} // End of 'for' statement
return true;
}
function f_getCertificateFromCaching(
in CertificatesCaching p_certificatesCaching,
in HashedId8 p_hashedId8,
) return boolean {
for (var integer v_counter := 0; v_counter < lengthof(p_certificatesCaching); v_counter := v_counter + 1) {
if (match(p_certificatesCaching[v_counter].hashedId8, p_hashedId8) == true) {
p_certificate := p_certificatesCaching[v_counter].certificate;
return true;
}
} // End of 'for' statement
return false;
}
function f_getCertificatesCachingItem(
in CertificatesCaching p_certificatesCaching,
in UInt8 p_index,
) return boolean {
if (lengthof(p_certificatesCaching) < p_index) {
p_certificate := p_certificatesCaching[p_index].certificate;
return true;
}
return false;
}
function f_getCertificatesCachingItemSize(
in CertificatesCaching p_certificatesCaching
) return UInt8 {
return lengthof(p_certificatesCaching);
}
}// End of group certificatesCaching
} // End of group helpersFunctions
* @desc Produces a 256-bit (32-byte) hash value
* @param p_toBeHashedData Data to be used to calculate the hash value
* @return The hash value
*/
external function fx_hashWithSha256(in octetstring p_toBeHashedData) return Oct32;
* @desc Produces a 384-bit (48-byte) hash value
* @param p_toBeHashedData Data to be used to calculate the hash value
* @return The hash value
*/
external function fx_hashWithSha384(in octetstring p_toBeHashedData) return Oct48;
* @desc Produces a Elliptic Curve Digital Signature Algorithm (ECDSA) signature
* @param p_toBeSignedSecuredMessage The data to be signed
* @param p_privateKey The private key
* @return The signature value
*/
external function fx_signWithEcdsaNistp256WithSha256(in Oct32 p_toBeSignedSecuredMessage, in Oct32 p_privateKey) return octetstring;
/**
* @desc Produces a Elliptic Curve Digital Signature Algorithm (ECDSA) signature
* @param p_toBeSignedSecuredMessage The data to be signed
* @param p_privateKey The private key
* @return The signature value
*/
external function fx_signWithEcdsaBrainpoolp256WithSha256(in Oct32 p_toBeSignedSecuredMessage, in Oct32 p_privateKey) return octetstring;
/**
* @desc Produces a Elliptic Curve Digital Signature Algorithm (ECDSA) signature
* @param p_toBeSignedSecuredMessage The data to be signed
* @param p_privateKey The private key
* @return The signature value
*/
external function fx_signWithEcdsaBrainpoolp384WithSha384(in Oct48 p_toBeSignedSecuredMessage, in Oct48 p_privateKey) return octetstring;
* @desc Verify the signature of the specified data
* @param p_toBeVerifiedData The data to be verified
* @param p_signature The signature
* @param p_ecdsaNistp256PublicKeyX The public key (x coordinate)
* @param p_ecdsaNistp256PublicKeyY The public key (y coordinate)
* @return true on success, false otherwise
*/
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external function fx_verifyWithEcdsaNistp256WithSha256(in Oct32 p_toBeVerifiedData, in octetstring p_signature, in Oct32 p_ecdsaNistp256PublicKeyX, in Oct32 p_ecdsaNistp256PublicKeyY) return boolean;
/**
* @desc Verify the signature of the specified data
* @param p_toBeVerifiedData The data to be verified
* @param p_signature The signature
* @param p_ecdsaBrainpoolp256PublicKeyX The public key (x coordinate)
* @param p_ecdsaBrainpoolp256PublicKeyY The public key (y coordinate)
* @return true on success, false otherwise
*/
external function fx_verifyWithEcdsaBrainpoolp256WithSha256(in Oct32 p_toBeVerifiedData, in octetstring p_signature, in Oct32 p_ecdsaBrainpoolp256PublicKeyX, in Oct32 p_ecdsaBrainpoolp256PublicKeyY) return boolean;
/**
* @desc Verify the signature of the specified data
* @param p_toBeVerifiedData The data to be verified
* @param p_signature The signature
* @param p_ecdsaBrainpoolp384PublicKeyX The public key (x coordinate)
* @param p_ecdsaBrainpoolp384PublicKeyY The public key (y coordinate)
* @return true on success, false otherwise
*/
external function fx_verifyWithEcdsaBrainpoolp384WithSha384(in Oct48 p_toBeVerifiedData, in octetstring p_signature, in Oct48 p_ecdsaBrainpoolp384PublicKeyX, in Oct48 p_ecdsaBrainpoolp384PublicKeyY) return boolean;
* @desc Produce a new public/private key pair based on Elliptic Curve Digital Signature Algorithm (ECDSA) algorithm.
* This function should not be used by the ATS
* @param p_privateKey The new private key value
* @param p_publicKeyX The new public key value (x coordinate)
* @param p_publicKeyX The new public key value (y coordinate)
* @return true on success, false otherwise
*/
external function fx_generateKeyPair_nistp256(out Oct32 p_privateKey, out Oct32 p_publicKeyX, out Oct32 p_publicKeyY) return boolean;
/**
* @desc Produce a new public/private key pair based on Elliptic Curve Digital Signature Algorithm (ECDSA) algorithm.
* This function should not be used by the ATS
* @param p_privateKey The new private key value
* @param p_publicKeyX The new public key value (x coordinate)
* @param p_publicKeyX The new public key value (y coordinate)
* @return true on success, false otherwise
*/
external function fx_generateKeyPair_brainpoolp256(out Oct32 p_privateKey, out Oct32 p_publicKeyX, out Oct32 p_publicKeyY) return boolean;
/**
* @desc Produce a new public/private key pair based on Elliptic Curve Digital Signature Algorithm (ECDSA) algorithm.
* This function should not be used by the ATS
* @param p_privateKey The new private key value
* @param p_publicKeyX The new public key value (x coordinate)
* @param p_publicKeyX The new public key value (y coordinate)
* @return true on success, false otherwise
*/
external function fx_generateKeyPair_brainpoolp384(out Oct48 p_privateKey, out Oct48 p_publicKeyX, out Oct48 p_publicKeyY) return boolean;
group encryption {
} // End of group encryption
group certificatesLoader {
/**
* @desc Load in memory cache the certificates available in the specified directory
* @param p_rootDirectory Root directory to access to the certificates identified by the certificate ID
* @param p_configId A configuration identifier
* @remark This method SHALL be call before any usage of certificates
* @return true on success, false otherwise
*/
external function fx_loadCertificates(in charstring p_rootDirectory, in charstring p_configId) return boolean;
external function fx_store_certificate(in charstring p_cert_id, in octetstring p_cert, in octetstring p_private_key, in octetstring p_public_key_x, in octetstring p_public_key_y, in octetstring p_hashid8, in octetstring p_issuer) return boolean;
* @desc Unload from memory cache the certificates
* @return true on success, false otherwise
*/
external function fx_unloadCertificates() return boolean;
* @desc Read the specified certificate
* @param p_certificateId the certificate identifier
* @param p_certificate the expected certificate
* @return true on success, false otherwise
*/
external function fx_readCertificate(in charstring p_certificateId, out octetstring p_certificate) return boolean;
/**
* @desc Read the specified certificate digest
* @param p_certificateId the certificate identifier
* @param p_digest the expected certificate
* @return true on success, false otherwise
*/
external function fx_readCertificateDigest(in charstring p_certificateId, out HashedId8 p_digest) return boolean;
* @desc Read the private keys for the specified certificate
* @param p_keysId the keys identifier
* @param p_signingPrivateKey the signing private key
* @return true on success, false otherwise
*/
external function fx_readSigningKey(in charstring p_keysId, out Oct32 p_signingPrivateKey) return boolean;
/**
* @desc Read the private keys for the specified certificate
* @param p_keysId the keys identifier
* @param p_encryptPrivateKey the encrypt private key
* @return true on success, false otherwise
*/
external function fx_readEncryptingKey(in charstring p_keysId, out Oct32 p_encryptingPrivateKey) return boolean;
} // End of group certificatesLoader
* @desc Check that given polygon doesn't have neither self-intersections nor holes.
* @param p_region Polygonal Region
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isValidPolygonalRegion(in PolygonalRegion p_region) return boolean;
* @desc Check if a polygonal region is inside another one
* @param p_parent The main polygonal region
* @param p_region The polygonal region to be included
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isPolygonalRegionInside(in PolygonalRegion p_parent, in PolygonalRegion p_region) return boolean;
* @desc Check that the location is inside a circular region
* @param p_region The circular region to consider
* @param p_location The device location
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isLocationInsideCircularRegion(in CircularRegion p_region, in ThreeDLocation p_location) return boolean;
* @desc Check that the location is inside a rectangular region
* @param p_region The rectangular region to consider
* @param p_location The device location
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isLocationInsideRectangularRegion(in SequenceOfRectangularRegion p_region, in ThreeDLocation p_location) return boolean;
* @desc Check that the location is inside a polygonal region
* @param p_region The polygonal region to consider
* @param p_location The device location
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isLocationInsidePolygonalRegion(in PolygonalRegion p_region, in ThreeDLocation p_location) return boolean;
* @desc Check if the location is inside an identified region
* @param p_region The identified region to consider
* @param p_location The device location
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isLocationInsideIdentifiedRegion(in IdentifiedRegion p_region, in ThreeDLocation p_location) return boolean;
/**
* @desc Check if the location is inside an undefined region
* @param p_region The identified region to consider
* @param p_location The device location
* @return true on success, false otherwise
* @verdict Unchanged
*/
external function fx_isLocationInsideOtherRegion(in octetstring p_region, in ThreeDLocation p_location) return boolean;
/**
* @desc Check that p_circular_region_1 circular region is included into p_circular_region_2 circular region
* @param p_circular_region_1 Circular region 1
* @param p_circular_region_2 Circular region 2
*
* @return true on success, false otherwise
*/
external function fx_areCirclesInside(in CircularRegion p_circular_region_1, in CircularRegion p_circular_region_2) return boolean;
/**
* @desc Check that p_rectanglar_region_1 rectangular region is included into p_rectanglar_region_2 rectangular region
* @param p_rectanglar_region_1 Rectangular region 1
* @param p_rectanglar_region_2 Rectangular region 2
*
* @return true on success, false otherwise
*/
external function fx_areRectanglesInside(in SequenceOfRectangularRegion p_rectanglar_region_1, in SequenceOfRectangularRegion p_rectanglar_region_2) return boolean;
/**
* @desc Check that p_polygonal_region_1 polygonal region is included into p_polygonal_region_2 polygonal region
* @param p_polygonal_region_1 Polygonal region 1
* @param p_polygonal_region_2 Polygonal region 2
*
* @return true on success, false otherwise
*/
external function fx_arePolygonsInside(in PolygonalRegion p_polygonal_region_1, in PolygonalRegion p_polygonal_region_2) return boolean;
* @desc Convert a spacial coordinate from DMS to Dms
* @param p_degrees The degrees (D)
* @param p_minutes The minutes (M)
* @param p_seconds The seconds (S)
* @param p_latlon The latitude/longitude: (N|S|E|W)
* @return The decimal coordinate on success, 0.0, otherwise
* @verdict Unchanged
*/
external function fx_dms2dd(in Int p_degrees, in Int p_minutes, in float p_seconds, in Oct1 p_latlon) return float;
} // End of group externalFunctions
in EtsiTs103097Certificate p_cert,
in EtsiTs103097Certificate p_cert_issuer
var ValidityPeriod v_cert_region, v_cert_issuer_region;
/* FIXME To be reviewed v_cert_issuer_region_result := f_getCertificateValidityRestriction(p_cert_issuer, e_region, v_cert_issuer_region);
if (f_getCertificateValidityRestriction(p_cert, e_region, v_cert_region) == false) {
if (v_cert_issuer_region_result == true) {
if (v_cert_issuer_region.validity.region.region_type != e_none) {
return false;
}
}
} else if (
(v_cert_issuer_region_result == true) and
(v_cert_issuer_region.validity.region.region_type != e_none)
if (v_cert_region.validity.region.region_type == e_circle) {
if (v_cert_issuer_region.validity.region.region_type == e_circle) {
// Check v_cert_region 'circle' is inside v_cert_issuer_region 'circle'
if (f_areCirclesInside(v_cert_region.validity.region.region.circular_region, v_cert_issuer_region.validity.region.region.circular_region) == false) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing certificates circle area does not match ***");
return false;
}
}
} else if (v_cert_region.validity.region.region_type == e_rectangle) {
if (v_cert_issuer_region.validity.region.region_type == e_rectangle) {
// Check v_cert_region 'rectangle' is inside v_cert_issuer_region 'rectangle'
if (f_areRectanglesInside(v_cert_region.validity.region.region.rectangular_region, v_cert_issuer_region.validity.region.region.rectangular_region) == false) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing certificates rectangle area does not match ***");
return false;
}
}
} else if (v_cert_region.validity.region.region_type == e_polygon) {
if (v_cert_issuer_region.validity.region.region_type == e_polygon) {
// Check v_cert_region 'polygon' is inside v_cert_issuer_region 'polygon'
if (f_arePolygonsInside(v_cert_region.validity.region.region.polygonal_region, v_cert_issuer_region.validity.region.region.polygonal_region) == false) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing certificates polygon area does not match ***");
return false;
}
}
} else if (v_cert_region.validity.region.region_type == e_id) {
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// Check id_region
if (not match (v_cert_region.validity.region, mw_geographicRegion_identified(mw_identifiedRegion_iso3166_any))) {
log("*** " & testcasename() & ": FAIL: Identified region is not conformed to ISO 3166-1 ***");
return false;
}
if (not match (v_cert_region.validity.region, mw_geographicRegion_identified(mw_identifiedRegion_un_stats_any))) {
log("*** " & testcasename() & ": FAIL: Identified region is not conformed to United Nations Statistics Division ***");
return false;
}
// Check region_dictionary
if (not match (v_cert_region.validity.region.region.id_region.region_dictionary, v_cert_issuer_region.validity.region.region.id_region.region_dictionary)) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing 'region_dictionary' field does not match ***");
return false;
}
// Check region_identifier
if (not match (v_cert_region.validity.region.region.id_region.region_identifier, v_cert_issuer_region.validity.region.region.id_region.region_identifier)) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing 'region_identifier' field does not match ***");
return false;
}
// Check local_region
if (
(not match (v_cert_issuer_region.validity.region.region.id_region.local_region, v_cert_region.validity.region.region.id_region.local_region)) or
(not match (v_cert_issuer_region.validity.region.region.id_region.local_region, 0))
) {
log("*** " & testcasename() & ": FAIL: Issuer and issuing 'local_region' field does not match ***");
return true;
} // End of function f_checkRegionValidityRestiction
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* @desc Check that p_circular_region_1 circular region is included into p_circular_region_2 circular region
* @param p_circular_region_1 Circular region 1
* @param p_circular_region_2 Circular region 2
*
* @return true on success, false otherwise
*/
function f_areCirclesInside(
in CircularRegion p_circular_region_1,
in CircularRegion p_circular_region_2
) return boolean {
return fx_areCirclesInside(p_circular_region_1, p_circular_region_2);
}
/**
* @desc Check that p_rectanglar_region_1 rectangular region is included into p_rectanglar_region_2 rectangular region
* @param p_rectanglar_region_1 Rectangular region 1
* @param p_rectanglar_region_2 Rectangular region 2
*
* @return true on success, false otherwise
*/
function f_areRectanglesInside(
in SequenceOfRectangularRegion p_rectanglar_region_1,
in SequenceOfRectangularRegion p_rectanglar_region_2
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) return boolean {
return fx_areRectanglesInside(p_rectanglar_region_1, p_rectanglar_region_2);
}
/**
* @desc Check that p_polygonal_region_1 polygonal region is included into p_polygonal_region_2 polygonal region
* @param p_polygonal_region_1 Polygonal region 1
* @param p_polygonal_region_2 Polygonal region 2
*
* @return true on success, false otherwise
*/
function f_arePolygonsInside(
in PolygonalRegion p_polygonal_region_1,
in PolygonalRegion p_polygonal_region_2
) return boolean {
return fx_arePolygonsInside(p_polygonal_region_1, p_polygonal_region_2);
}
/**
* @desc Check that given location is valid
* @param p_location location to be checked
* @return true on success, false otherwise
*/
//FIXME RGY Titan doesn't support dot notation after valueof at the moment